hvdc systems_in_india

1. HVDC Systems in India

2. Outline
 Introduction
 HVDC Systems presently in operation
– Main Data/Salient Features
 Upcoming Projects
 Future Challenges

3.  765kV/400kV lines: about 1,03,000 ckms
 220kV lines: about 132,000 ckms
 HVDC Bipole(±500kV): 7,500 ckms–3
nos.
 HVDC Back-to-back: 7 nos. (3000MW)
 FSC – 22 nos.; TCSC – 6 nos.
Transmission Network - Present

4. Inter-regional Capacity –
22,400MW
National Grid – Present

5.  Coal – In Central India
‾ Chhattisgarh : 58000 MW
‾ Orissa : 30000 MW
‾ Jharkhand : 15000 MW
‾ Madhya Pradesh:16000 MW
 Hydro – In North Eastern &
Northern Himalayan region
 Coastal based
‾ Andhra Pradesh: 24000 MW
‾ Tamil Nadu : 10000 MW
‾ Gujarat : 11000 MW
Energy resources (coal, water etc.) unevenly distributed
Energy Resources Map

6. Creation of Transmission Highways
Cluster of Concentrated
Demand pockets
Cluster of Generation
pockets

7. 1977 1990 2000 2012 2014/15
Increase in Transmission voltage
Voltage
(kV)
Year
220kV
400kV
500kV
HVDC
765kV
800kV
HVDC
1200kV

8. 96 m 46 m
400 kV AC Lines ±500 kV DC Line
Comparison of right of way

9. Voltage wise Trans. Corridor Density
Voltage 132 kV 220 kV 400 kV 765 Kv +500 kV
HVDC
+800 kV
HVDC
(approx)
1200 kV
(approx)
ROW
Meters(M)
27 35
52
(400 KV S/C
Twin Moose Conductor )
64
( 765 KV S/C
Quad Bersimis
conductor)
46 70 90
Capacity
(MW)
(Typical values of
Stability Limits for
AC system)
70-80
160-170 500-600 2500-3000 2000-2500 6000-6400 6000-8000
MW/m 3 5 15 45 48 90 90

10. Advantages of HVDC
 Controlled Power Exchange
 Improve stability of AC system
 Transmission at Reduced Voltage
 Minimize power reduction in case of pole outage
 Benefits at low ambient temperature
 Asynchronous link

11. HVDC Systems presently in operation
(Main Data/Salient Features)

12. ± 500 kV , 1500 MW Rihand – Dadri HVDC Project.
Main Data:
Power rating : 1500MW
No. of Poles : 2
AC Voltage : 400 kV
DC Voltage : + 500 kV
Converter Transformer-
Rihand Terminal : 6 x 315 MVA
Dadri Terminal : 6 x 305 MVA
Length of over head DC line: 816 KM.
Date of Commisioning: Dec-1991

13.  ±500kV,1500MW HVDC Bi-Pole Transmission link
supplies Bulk Power from Thermal Power Plant of
Rihand (Eastern part of Northern Grid) to Dadri
(Western part of Northern Grid).
 Each pole continuous power carrying capacity is 750
MW with 10% two hours overload and 33% five
seconds overload capability .
 Reverse power flow capability available.
 During inclement weather condition power
transmission is possible at ±400 kV DC voltage.
System Salient Features:
± 500 kV , 1500 MW Rihand – Dadri HVDC Project.

14. 2 x 250 MW HVDC Vindhyachal Back to Back Station.
Completion date: April 1989
Main Data:
(i) Power rating : 2 x 250 MW.
(ii) No. of Blocks : 2
(iii) AC Voltage : 400 kV
(iv) DC Voltage : ± 70 kV
(v) Converter Transformer : 8 x 156 MVA

15. System Salient Features:
(i) It connects Vindhyachal Super Thermal Power Stations (Western
Region) to Singrauli Super Thermal Power Stations (Northern Region) in
Indian Grid.
(ii) Each Block power carrying capacity is 250 MW.
(iii) Bidirectional power flow capability is available.
(iv) The project achieve load diversity of Northern and Western region in Indian Grid
by meeting high demand from surplus power available in either regions
(v) First commercial Back to Back HVDC Station in India
2 x 250 MW HVDC Vindhyachal Back to Back
Station.

16. 2 x 500 MW HVDC Chandrapur Back to Back Station.
Start date: November 1993
Completion date: Dec 1997
Main Data:
Power rating : 2 x 500 MW.
No. of Blocks : 2
AC Voltage : 400 kV
DC Voltage : 205 kV
Converter Transformer : 12 x 234 MVA

17. System Salient Features:
(i) It connects Chandrapur Thermal Power Stations (Western Region) to
Ramagundum (Southern Region) Thermal Power Stations in Indian
Grid.
(ii) Each Block power carrying capacity is 500 MW.
(iii) Bidirectional power flow capability is available.
(iv) The project achieve load diversity of Western and Southern region in
Indian Grid by meeting high demand from surplus power available in
either regions
(v) Second commercial Back to Back HVDC Station in India.
2 x 500 MW HVDC Chandrapur Back to Back Station.

18. + 500 kV ,2000 MW, HVDC Talchar – Kolar Transmission
Link
Completion date: June 2003
Main Data:
Power rating : 2000 MW
No. of Poles : 2
AC Voltage : 400 kV
DC Voltage : + 500 kV
Converter Transformer-
Talcher : 6 x 398 MVA
Kolar : 6 x 398 MVA
Length of over head DC line: 1369 KM.
This is the longest (1369 Km.) commercial HVDC link in India

19.  HVDC Talchar – Kolar link was designed for 2000 MW continuous rating
with inherent short term overload capacity depending on-
Ambient temperature
Prevailing voltages at Talcher and Kolar
Cooling mechanism.
 Further, DC Bipole lines with quad conductor was capable to transmit 1250
MW continuously with marginal incremental loss .
 The inherent overload capability was utilized to meet the system
contingencies by up gradation of Talcher – Kolar HVDC link capacity from
2000 MW to 2500 MW .
 This enhanced capacity is to be used only under contingency and not for
increasing HVDC Capacity for firm transfer of 2500 MW
Up gradation of + 500 kV HVDC Talchar – Kolar link from
2000 MW to 2500 MW

20. 1 x 500 MW HVDC Sasaram Back to Back Station.
Completion date: Sep 2002
Main Data
(i) Power rating : 1 x 500 MW.
(ii) No. of Blocks : 1
(iii) AC Voltage : 400 kV
(iv) DC Voltage : 205 kV
(v) Converter Transformer : 6 x 234 MVA
Connects Pusauli (Eastern Region) to Sasaram (Eastern part of Northern Grid) of
Indian Grid (Power Transfer mainly from ER to NR)

21. 2 x 500 MW HVDC Gazuwaka Back to Back Station.
Completion date: Block 1 : Feb 1999
Block 2 : March 2005
Main Data:
(i) Power rating : 2 x 500 MW.
(ii) No. of Blocks : 2
(iii) AC Voltage : 400 k
(iv) DC Voltage : 205 kV ( Block 1)
177 kV (Block 2 )
(v) Converter Transformer
Block 1 : 6 x 234 MVA
Block 2 : 6 x 201.2 MVA

22. 2 x 500 MW HVDC Gazuwaka Back to Back Station.
System Salient Feature
(i) It connects Jeypore (Eastern Region) to Gazuwaka (Southern Region)
Thermal Power Stations of Indian Grid
(ii) Each Block power carrying capacity is 500 MW.
(iii) Bidirectional power flow capability available.
(iv) The project achieve load diversity of Eastern and Southern region in Indian
Grid by meeting high demand from surplus power available

23. + 500 kV, 2500 MW HVDC Ballia – Bhiwadi Transmission
Link.
Pole 1 Commissioned on 31-03 10
Main Data:
Power rating : 2500 MW
No. of Poles : 2
AC Voltage : 400 kV
DC Voltage : + 500 kV
Length of over head DC line : 780 Km.
Converter Transformer
Ballia : 8 x 498 MVA
Bhiwadi 8 x 498 MVA

24. (i) Bi-Pole + 500 kV, 2500 MW HVDC 780 km
Transmission lines from Ballia (Eastern part
of India) to Bhiwadi (Northern part of India)
of Indian Grid.
(ii) Each pole power carrying capacity is 1250 MW.
(iii) During unfavorable weather condition, operation
at 70% to 80% DC voltage is possible.
(iv) Reverse power flow capability is available.
+ 500 kV, 2500 MW HVDC Ballia – Bhiwadi Transmission
Link
System Salient Features:

25. + 500 kV, 2500 MW HVDC Ballia – Bhiwadi Transmission
Link
 Arrangement of Spare Converter
Transformer for quick restoration of
Pole in case of failure of Converter
Transformer.
 Each Pole is having a dedicated Spare
Converter Transformer with
switching arrangement.
 Transformer Configuration being
used for the first time.
Switchable Configuration of Spare Converter Transformer

26. Upcoming Projects

27. 800 KV HVDC Multi Terminal System
 North-Eastern Region has a large quantum Hydro Electric Power potential.
 Under Hydro Development program of Govt of India, this power has to be evacuated to
load centres of Northern and Western Regions

28. 800 KV HVDC Multi Terminal System
POWERGRID is installing +/-800 kV,
6000 MW HVDC multi-terminal system
of approx length of 1728 km from North
Eastern Region to Agra
One Rectifier station in Biswanath
Chariali (in North Eastern Region), second
one in Alipurduar (in Eastern Region) and
Inverter station at Agra (in Northern
Region)

29.  Converter stations at Biswanath Chariali and Alipurduar each handles a
power of 3000 MW and Converter station at Agra handles 6000 MW
power
 This Tr. System originates from Assam and passes through West Bengal,
Bihar and terminates in Uttar Pradesh
 First Multi Terminal project in India
800 KV HVDC Multi Terminal System

30. 400 KV Alipurduar
Biswanath Ch. to Alipurduar
800 KV HVDC Multi Terminal System

31.  First ±800 KV Multi-Terminal HVDC project in the world.
 First 12 pulse 800 KV terminal of the world
 First Multi-Terminal with continuous 33% overload feature
 After considering the continuous 33% overload feature, this will be
the highest capacity HVDC project of the world.
 Each pole of the Multi-terminal shall be designed for 2000 MW which
is the highest capacity poles in the world.
 The Earth electrode shall be designed for 5000 A DC continuous
current which shall be 1st
of its kind in the world.
Salient features of 800 KV multi-terminal
HVDC project

32. HVDC Multi terminal System- Advantages
•Create power pooling points to collect power from Several Generating
Stations and to transport it on ± 800 kV DC bipolar lines (power highway) to
major Load Centers located far away
•Efficient Utilization of ± 800 kV Line by connecting parallel HVDC
Converters physically at different locations ( eg Rectifiers 450 km apart) to the
same.
• 33 % Continuous Overload Capability gives higher availability for Nominal
Power Transmission -(For North East –Agra Multi terminal)

33. 1 X 500 MW India Bangladesh Interconnector project

34. 1 X 500 MW India Bangladesh Interconnector project
The first interconnection between Eastern Region, India
and Western Grid, Bangladesh
POWERGRID’s Consultancy assignment
Scope –
Pre Award Engineering
Finalisation of Bidding Documents, Assistance in Tender evaluation,
Post Award Engineering
Construction Supervision

35. 185 Kms
90 Kms
150 Kms
Proposed Route for Interconnection
Madurai
Rameshwaram
Anuradhapura
Talaimannar
India – Sri Lanka Interconnection

36. Indo-Srilanka HVDC Inter Connecter Link
• ± 400 kV, 4 x 250 MW HVDC Bipole Transmission Link
• From Madurai (India) to Sri Anuradhapura (Sri Lanka)
• Project having Overhead line (app 334 km) and Submarine Cable ( app 90 Km)
India Sri LankaSea
Submarine Cable
Overhead line Overhead line
Transmission System in the Sea Route : Submarine Cable

37. Champa- Kurukshetra ± 800 KV , 3000 MW HVDC Link
 IPP generation projects coming up in Chhattisgarh for transfer of
power to different target regions viz. Western and Northern region.
 Above generation projects are mainly coming up in Raigarh (near
Kotra), Champa-Janjgir and Raigarh (Near Tamnar) complex.
 Based on the transmission system requirement for transfer of power
to Northern Region from these generation projects , following WR –
NR interconnector for IPP Projects in Chhattisgarh is proposed :-
 Establishment of 3000MW 800KV HVDC Bipole Terminal
Station each at Champa Pooling Station (WR) and
Kurukshetra (NR) respectively (provision to upgrade the
terminals at 6000MW at a later date).

38. Champa- Kurukshetra
± 800 KV , 3000 MW HVDC
Link (upgradable to 6000 MW by
parallel converters)
- Return Current (both Monopolar
and Bipolar) through Third
Conductor
Champa- Kurukshetra ± 800 KV , 3000 MWChampa- Kurukshetra ± 800 KV , 3000 MW
HVDC LinkHVDC Link

39. Advantages of having Third Conductor for Return path:
 It eliminates the element of uncertainty about the proper functionality
of the earth electrode station.
 It shall avoid acquisition of separate land for each earth electrode stations,
construction of electrode stations which involves requirement
of large amount of steel rods and coke.
 The construction of new Transmission Line between Earth Electrode
Station and respective HVDC terminal station shall be avoided.

40. Future Challenges

41.  Transmission growth driven by
 Strong GDP growth – requiring massive expansion of
Power Sector
 Uneven distribution of energy resources
 Change in generation profile
Growth Drivers

42. 100
152
218
437
323
2007 2012 2017 2022 2027
Year
GW
Peak Demand
132
220
306
575
425
2007 2012 2017 2022 2027
Year
GW
73 GW
101 GW
119 GW
150 GW
Installed Capacity Requirement
End of X plan
During 12th
plan
During 13th
plan
During 11th
plan
205
Future Power Scenario

43. Need of new initiatives in Transmission
 Need of long distance Transmission system
 Minimum use of land and Right-of-Way
 Optimal cost per MW transmission
 Optimal Transmission Losses

44. HVDC Technology….
One of the Solution….